A Model for Fatigue Crack Growth in the Paris Regime under the Variability of Cyclic Hardening and Elastic Properties-Reference-Cited by-同舟云学术

A Model for Fatigue Crack Growth in the Paris Regime under the Variability of Cyclic Hardening and Elastic Properties

Published:2017-12-01 Issue:9 Volume:2017 Page:117-135
ISSN:2300-7591
Container-title:Fatigue of Aircraft Structures
language:en
Short-container-title:

Author:

Kebir Tayeb¹,Benguediab Mohamed¹,Imad Abdellatif²

Affiliation:

1. Department of Mechanical Engineering, Faculty of Technology , Laboratory of Materials and Reactive Systems (LMRS) , University of Sidi Bel-Abbes , Algeria

2. Polytech’Lille1 , Laboratory of Mechanical of Lille (LML) , University of Lille1 , France

Abstract

Abstract Over the last 60 years, several models have been developed governing different zones of fatigue crack growth from the threshold zone to final failure. The best known model is the Paris law and a number of its based on mechanical, metallurgical and loading parameters governing the propagation of cracks. This paper presents an analytical model developed to predict the fatigue crack propagation rate in the Paris regime, for different material properties, yield strength (σy), Young’s modulus (E) and cyclic hardening parameters (K’, n’) and their influence by variability. The cyclic plastic deformation at a crack tip or any other cyclic hardening rule may be used to reach this objective, for to investigate this influence, these properties of the model are calibrated using available experimental data in the literature. This FCGR model was validated on Al-alloys specimens under constant amplitude load and shows good agreement with the experimental results.

Publisher

Walter de Gruyter GmbH

Subject

Mechanics of Materials,Safety, Risk, Reliability and Quality,Aerospace Engineering,Civil and Structural Engineering

Reference55 articles.

1. [1] N. Vikram and R. Kumar, “Review on fatigue-crack growth and finite element method,” Int. J. Sci. Eng. Res., vol. 4, no. 4, pp. 833–843, 2013.

2. [2] F. Bergner, G. Zouhar, and G. Tempus, “The material-dependent variability of fatigue crack growth rates of aluminium alloys in the Paris regime,” Int. J. Fatigue, vol. 23, pp. 383–394, 2001.

3. [3] J. H. Melson, “Fatigue crack growth analysis with finite element methods and a monte carlo simulation,” Thesis Master, Faculty of the Virginia Polytechnic Institute, 2014.

4. [4] T. Mann, “The influence of mean stress on fatigue crack propagation in aluminium alloys,” Int. J. Fatigue, vol. 29, no. 8, pp. 1393–1401, 2007.

5. [5] A. E. M. Alaoui, “Influence du chargement sur la propagation en fatigue de fissures courtes dans un acier de construction navale,” Thesis Doctor, University of Metz, 2005.

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